Proteolytic processing of QSOX1A ensures efficient secretion of a

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Biochem. J. (2013) 454, 181–190 (Printed in Great Britain)
181
doi:10.1042/BJ20130360
Proteolytic processing of QSOX1A ensures efficient secretion of a potent
disulfide catalyst
Jana RUDOLF*, Marie A. PRINGLE* and Neil J. BULLEID*1
*Institute of Molecular, Cellular and Systems Biology, College of Medical Veterinary and Life Sciences, Davidson Building, University of Glasgow, Glasgow G12 8QQ, U.K.
QSOX1 (quiescin sulfhydryl oxidase 1) efficiently catalyses the
insertion of disulfide bonds into a wide range of proteins. The
enzyme is mechanistically well characterized, but its subcellular
location and the identity of its protein substrates remain illdefined. The function of QSOX1 is likely to involve disulfide
formation in proteins entering the secretory pathway or outside
the cell. In the present study, we show that this enzyme is
efficiently secreted from mammalian cells despite the presence
of a transmembrane domain. We identify internal cleavage sites
and demonstrate that the protein is processed within the Golgi
apparatus to yield soluble enzyme. As a consequence of this
efficient processing, QSOX1 is probably functional outside the
cell. Also, QSOX1 forms a dimer upon cleavage of the Cterminal domain. The processing of QSOX1 suggests a novel
level of regulation of secretion of this potent disulfide catalyst
and producer of hydrogen peroxide.
INTRODUCTION
and can be secreted from a variety of tissues and is present in
most bodily fluids [7,8]. The relative roles of QSOX1A and
QSOX1B have been difficult to determine because of the identical
protein sequence of QSOX1B and part of the ectodomain of
QSOX1A, which compromises antibody localization studies. It is
most likely that they have the same enzymatic function, but may
fulfil their role in different cellular and extracellular environments.
Both QSOX1 and QSOX2 are expressed in most tissues, but
QSOX2 is much less abundant than QSOX1 [9]. QSOX2 shares
35 % identity with QSOX1A having the same overall domain
structure and containing a TM domain that confers membrane
localization [10]. The significance of the presence of the different
QSOX isoforms is unclear, as is the identity of any physiological
substrates.
Although the precise function of QSOX1 remains elusive, what
is known is that the expression of the enzyme is elevated in certain
disease states. QSOX1 was originally identified as a protein that
is up-regulated during the transition of cells into quiescence [11].
The protein has also been shown to be elevated in serum following
heart failure and can therefore act as a prominent biomarker for
cardiovascular disease [12]. In addition, QSOX1 expression is
highly up-regulated during prostate tumorigenesis [13,14] and
breast cancer [15], suggesting a role for this protein in cancer
progression.
Even though QSOX1A contains a TM domain, plasma from
patients with adenocarcinoma of the pancreas were found to
contain a peptide that could only be derived from QSOX1A,
suggesting that the protein is proteolytically cleaved during
carcinogenesis [16]. To investigate the potential processing
of QSOX1A, we studied its trafficking when expressed in
mammalian cells. Our results demonstrate that the protein is
initially membrane-associated, but is efficiently cleaved and
secreted. In addition, the secreted processed protein exists as a
QSOX1 (quiescin sulfhydryl oxidase 1) is an enzyme that can
introduce disulfides into a wide range of proteins using molecular
oxygen as an electron acceptor. It is a chimaera of two protein
families as it contains both a disulfide-exchange (thioredoxin-like)
and an oxidase (Erv-like) domain [1]. Its mechanism of action is
well characterized in vitro, involving an initial disulfide exchange
between the thioredoxin domain and substrate, and an internal
electron transfer leading to the reduction of FAD to FADH2 within
the Erv domain [2,3]. The FADH2 rapidly reduces molecular
oxygen to liberate hydrogen peroxide. Hence, for every disulfide
introduced into a protein substrate, one oxygen and hydrogen
peroxide molecule is consumed and produced respectively. The
reaction catalysed by QSOX1 is equivalent to that catalysed by a
combination of Ero1 (endoplasmic reticulum oxidase 1) and PDI
(protein disulfide-isomerase) in the ER (endoplasmic reticulum).
However, the catalytic efficiency of QSOX1 is several orders
of magnitude greater than Ero1, giving rise to the possibility
that QSOX1 may have a role in catalysing disulfide formation
in the ER [4]. Such a role has been given more credence by
the observation that, when overexpressed, human QSOX1 can
complement a yeast strain deficient in Ero1 activity [5]. However,
although QSOX1 is synthesized in the ER, its subcellular location
seems to be primarily in the Golgi apparatus [5], which may
preclude any function in the ER.
There are two isoforms of QSOX expressed in mammalian cells:
QSOX1 and QSOX2 [6]. In addition, QSOX1 exists in two splice
variants: QSOX1A and QSOX1B (Figure 1A). QSOX1A contains
an additional 143 amino acids at the C-terminus, including a TM
(transmembrane) domain. When newly synthesized, QSOX1A
is localized to the membrane fraction, indicating that the TM
domain is functional [5]. QSOX1B is not membrane-associated
Key words: disulfide formation, proprotein convertase, proteolytic
processing, quiescin sulfhydryl oxidase 1 (QSOX1), sulfhydryl
oxidase.
Abbreviations used: BMH, 1,6-bismaleimidohexane; CHO, Chinese-hamster ovary; DDM, dodecylmaltoside; DMEM, Dulbecco’s modified Eagle’s
medium; EndoH, endoglycosidase H; ER, endoplasmic reticulum; Ero1, endoplasmic reticulum oxidase 1; GAPDH, glyceraldehyde-3-phosphate
dehydrogenase; GM130, cis -Golgi matrix protein of 130 kDa; NEM, N -ethylmaleimide; PDI, protein disulfide-isomerase; PNGase, peptide N-glycosidase;
PPC, proprotein convertase; QSOX, quiescin sulfhydryl oxidase; SEC, size-exclusion chromatography; TBST, TBS containing 0.1 % Tween 20; TCA,
trichloroacetic acid; TM, transmembrane.
1
To whom correspondence should be addressed (email neil.bulleid@glasgow.ac.uk).
c The Authors Journal compilation c 2013 Biochemical Society
182
J. Rudolf, M. A. Pringle and N. J. Bulleid
EXPERIMENTAL
Antibodies
The anti-QSOX1A antibody was raised in rabbit using the
peptide EPPEHMAELQRNEQEQPL and affinity-purified. A
rabbit anti-QSOX1 antibody that recognizes both QSOX1A
and QSOX1B was a gift from Professor Debbie Fass
(Weizmann Institute of Science, Rehovot, Israel). Rabbit antiPDI antibody was as described previously [17] and the mouse
anti-PDI antibody (1D3) was a gift from Professor David
Vaux (University of Oxford, Oxford, U.K.). Mouse anti-MHC
class I (HC10) [18] and rabbit anti-GM130 (cis-Golgi matrix
protein of 130 kDa) antbodies were gifts from Dr Adam
Benham (University of Durham, Durham, U.K.) and Professor
Martin Lowe (University of Manchester, Manchester, U.K.)
respectively. The remaining antibodies were purchased from the
following companies: mouse anti-GAPDH (glyceraldehyde-3phosphate dehydrogenase) (Ambion), rabbit anti-actin (Sigma),
mouse anti-giantin (Abcam), mouse anti-V5 and anti-V5–
agarose (Invitrogen), rabbit anti-V5 (Sigma) and rabbit antiGFP (Thermo-Scientific). The following fluorescent-conjugated
secondary antibodies were purchased: FITC-conjugated antirabbit and anti-mouse (Sigma), Texas Red-conjugated anti-rabbit
and anti-mouse (Abcam), 680 and 800-conjugated anti-(mouse
IgG) and anti-(rabbit IgG) (either Li-Cor IRDye or ThermoScientific DyeLight). Mouse anti-V5–agarose was purchased
from Sigma and GFP-Trap® _A was from Chromotek.
Cell lines and cell culturing
Figure 1
Expression and secretion of human QSOX1A
(A) The QSOX1 constructs used in the present study are shown. Upper panel: the QSOX1A
sequence including the C-terminal single-pass TM domain followed by a V5-tag (V5). The
epitope detected by the anti-QSOX1A antibody is located on a linker that connects the Erv and
TM domain. Middle panel: the same as above, only the C-terminal V5 tag is changed to a GFP
tag. Lower panel: V5-tagged QSOX1B. (B) Western blots showing the expression and secretion
of QSOX1A–V5 (1A) and QSOX1B–V5 (1B). Cell lysates were prepared from HT1080 cells stably
overexpressing V5-tagged forms of either QSOX1A or QSOX1B. The secretion of proteins was
allowed for 3 h into serum-free medium followed by TCA precipitation. Nitrocellulose membranes
were co-probed for V5 (secondary DyLight680) and QSOX1A (secondary DyLight800). Molecular
masses of marker proteins are indicated (in kDa). (C) Secretion of overexpressed forms of
QSOX1A–V5 (1A), QSOX1B–V5 (1B) and endogenous QSOX1 forms (HT) is shown. Secretion
of QSOX1 into serum-free medium was allowed for 3 h and proteins were affinity-purified using
concanavalin A–Sepharose. Gel loading was adjusted according to the estimated secretion levels
of QSOX1 from different cell lines. Nitrocellulose membranes were probed using an antibody
detecting both forms of QSOX1 (α-1A/B). Molecular masses of marker proteins are indicated
(in kDa). (D) A CHO cell line stably expressing human QSOX1A–V5 ( + ) was compared to
untransfected CHO cells ( − ). Cell lysates and medium were prepared and analysed as described
in (B). (E) Proteinase K protection assay. Semi-permeabilized QSOX1A–V5-expressing cells
were incubated in the presence ( + ) or absence ( − ) of proteinase K (prot K) and/or Triton
X-100 (TX100). Nitrocellulose membranes were co-probed for the V5 and QSOX1A epitopes
(see B) and PDI (α-PDI), an ER marker indicating integrity of the inner membranes.
dimer. QSOX1A and QSOX1B are capable of associating within
cells, which could potentially prevent secretion of QSOX1B until
QSOX1A is proteolytically cleaved. These observations provide
compelling evidence that the enzyme is functional as a soluble
protein outside the cell and provide an indication of how the
trafficking and function of both splice variants may be regulated
by intracellular proteolytic processing.
c The Authors Journal compilation c 2013 Biochemical Society
HT1080-based cell lines were cultured in DMEM (Dulbecco’s
modified Eagle’s medium) (Gibco) and CHO (Chinese-hamster
ovary) cells were grown in Ham’s F12 medium (Sigma). Growth
media were supplemented with 10 % (v/v) FBS (Sigma) and
penicillin/streptomycin (Gibco). The HT1080 and the CHO cell
lines stably overexpressing QSOX1A-V5 were generated as
described in [5]. The QSOX1A–GFP fusion was created by using
the QSOX1A–V5/His construct as a template and cloning the
entire sequence upstream of the V5-tag in the pEGFP vector
(Clontech). QSOX1A–GFP was then subcloned into pcDNA3.1
Hygro (Invitrogen) for expression in mammalian cells. The
same template was used to create the QSOX1B–V5 construct.
Stable cell lines were created using polyethyleneimine-mediated
transfection [19] (Polysciences).
Deglycosylation
Cells were harvested, washed and lysed in lysis buffer [50 mM
Tris/HCl, pH 8.0, containing 150 mM NaCl, 5 mM EDTA and
1 % (w/v) Triton X-100] to give a concentration of 1.5×104
cells/μl. Lysates were cleared by centrifugation at 20 000 g
for 10 min at 4 ◦ C, and reactions were set up following the
manufacturer’s protocol (NEB). The samples were digested
overnight at 37 ◦ C using 500 units of either EndoH (endoglycosidase H) or PNGase (peptide N-glycosidase) and separated by
SDS/PAGE (7.5 % gel).
Membrane fractionation
For detection of soluble eGFP, HT1080 cells were transfected
transiently with pCAsalEGFP [20] and cells were harvested after
18 h. HT1080 cells stably overexpressing QSOX1A–GFP were
used for the detection of QSOX1A–GFP. Cells were washed with
PBS and resuspended in 2 ml of homogenization buffer (50 mM
Proteolytic processing of QSOX1A
Tris/HCl, pH 7.4, containing 250 mM sucrose, 50 mM KCl, 5 mM
MgCl2 , 1 mM EDTA, 0.5 mM PMSF and 1 mM DTT). Cells
were homogenized by ten passes through a 12-μm clearance
ball-bearing homogenizer (Isobiotec). Lysates were centrifuged
at 1000 g for 2 min at 4 ◦ C, and the pellet, containing the
nuclear fraction, was washed with 2 ml of homogenization buffer
and stored on ice. The supernatant was centrifuged at 16 000 g
for 75 min at 4 ◦ C, and the pellet, containing the membrane
fraction, was washed with 2 ml of homogenization buffer and
stored on ice. The supernatant was precipitated with 10 % (w/v)
TCA (trichloroacetic acid) and 0.4 mg/ml deoxycholate, and the
resulting pellet was washed with 80 % (v/v) acetone. All pellets
were resuspended in equal volumes of buffer A and analysed by
SDS/PAGE (10 % gel).
Pulse–chase and immunoisolation of QSOX1A
Experiments were essentially carried out as described in [5]. In
brief, cells were starved for 30 min in cysteine/methionine-free
DMEM and then radiolabelled in the same medium containing
EasyTagTM EXPRESS35 S Protein Labeling Mix (Pierce) (0.4
MBq/ml). After 30 min of incubation at 37 ◦ C the radiolabel
was removed, and cells were washed with PBS and incubated in
complete DMEM (containing 0.5 mM cycloheximide) for various
lengths of time. At specific time points, the medium was removed,
centrifuged at 250 g for 5 min to remove contaminating cells
and transferred to a fresh tube containing Protease Inhibitor
Cocktail (Roche) and sodium azide to a final concentration of
0.02 %. Cells were washed with PBS, before being lysed in RIPA
buffer (50 mM Tris/HCl, pH 7.5, containing 150 mM NaCl, 1 %
Nonidet P40, 0.5 % deoxycholate and Roche protease inhibitor
cocktail). Cell debris was removed by centrifugation at 20 000 g
for 3 min at 4 ◦ C. The lysates and the medium were pre-cleared
by adding Protein A–Sepharose (Generon) and incubated for
30 min at 4 ◦ C. Samples were subjected to immunoisolation by
using anti-V5–agarose, GFP-Trap® _A or Protein A–Sepharose
and anti-QSOX1A. Samples were incubated at 4 ◦ C either for
2 h (V5 and GFP) or overnight (QSOX1A) on a roller table.
The Sepharose beads were pelleted by centrifugation at 800 g
for 1 min and washed three times with 1 ml of RIPA buffer. An
equal volume of SDS sample buffer (100 mM Tris/HCl, pH 6.8,
containing 200 mM DTT, 4 % SDS, 0.1 % Bromophenol Blue and
20 % glycerol) was added, and the samples were boiled for 10 min
before separation by SDS/PAGE (8 % gel for QSOX1A–V5 and
11 % gel for QSOX1A–GFP). Gels were fixed, dried and exposed
to phosphor plate or imaging film (Kodak BioMax MR film).
Concanavalin A purification of secreted QSOX1
HT1080 cells stably overexpressing QSOX1A–V5 or QSOX1B–
V5 and untransfected cells were incubated with serum-free
medium for 3 h. The medium was harvested, contaminating
cells removed by centrifugation at 250 g for 5 min, and protease
inhibitor cocktail and sodium azide were added. The samples were
pre-cleared with Protein A–Sepharose (30 min at 4 ◦ C) before
being incubated in the presence of 20 μl of concanavalin A–
Sepharose 4B (Sigma) and divalent metal ions (1 mM MgCl2 ,
1 mM MnCl2 and 1 mM CaCl2 ) for 16 h at 4 ◦ C on a roller table.
Concanavalin A–Sepharose beads were isolated by centrifugation
at 800 g for 1 min and washed three times with 1 ml of RIPA
buffer. The volume of SDS sample buffer added was adjusted
according to the estimated expression levels of the QSOX1 in
these different cell lines. Finally, the samples were boiled and
equal volumes were analysed by SDS/PAGE (11 % gel).
183
Immunoblotting
After separation by SDS/PAGE, proteins were transferred on to
nitrocellulose membranes (Li-cor Biosciences). Membranes were
blocked in 3 % (w/v) non-fat dried skimmed milk powder in TBST
(TBS containing 0.1 % Tween 20) and incubated for 16 h at 4 ◦ C
in the presence of primary antibodies. Membranes were incubated
with the secondary fluorescent-conjugated antibodies for 45 min
in TBST. Western blots were visualized on an Odyssey® SA IR
scanner.
Immunofluorescence and live-cell microscopy
Cells were grown on 13-mm-diameter coverslips (ThermoScientific) and immunostained as described previously [21]. After
fixing with ice-cold methanol (5 min), cells were blocked in 1 %
(w/v) BSA in PBS for 45 min, followed by 30 min incubations
each for the primary and then secondary antibody in 0.2 % BSA
in PBS at 20 ◦ C. Slides were mounted in Mowiol® (Calbiochem)
containing 25 μg/ml DABCO (1,4-diazadicyclo[2.2.2]octane)
(Sigma). Images were taken either with a LSM Pascal Exciter
or a LSM 510 Meta confocal microscope (Zeiss). For live-cell
microscopy, cells were grown in glass-bottomed culture dishes
(35-mm-diameter Petri dish/10-mm-diameter microwell, MatTek
Corp.), washed extensively with Hepes buffer (20 mM Hepes,
pH 7.4, containing 130 mM NaCl, 5 mM KCl, 1 mM CaCl2 , 1 mM
MgCl2 and 10 mM D-glucose) and imaged on a LSM 510 Meta
confocal microscope in Hepes buffer.
Proteinase K protection assay
Semi-permeabilized cells were prepared as described in [22].
Proteinase K was added to a final concentration of 0.25 μg/ml to
1.5×105 cells in KHM buffer (20 mM Hepes, pH 7.2, containing
110 mM potassium acetate and 2 mM MgCl2 ). Where appropriate, 1 % (v/v) Triton X-100 was added. Reaction mixtures were
incubated on ice for 30 min and stopped by the addition of 200 μl
of PBS containing 1 mM PMSF and 2 mM EGTA. Samples were
centrifuged at 250 g for 5 min, supernatant was removed, and the
pellets were resuspended in lysis buffer. Reactions were cleared
by centrifugation at 20 000 g for 5 min at 4 ◦ C and analysed by
SDS/PAGE (11 % gel).
BMH (1,6-bismaleimidohexane) cross-linking
BMH (Thermo-Scientific) was made up fresh in DMSO. Cells
were detached with trypsin and washed with PBS, and cell
pellets were resuspended in KHM buffer. BMH was added to the
cell suspensions to a final concentration of 0.1 mM and samples
were incubated on ice for 30 min. Reactions were stopped by the
addition of 20 mM DTT for 5 min. Cells were pelleted at 250 g for
5 min at 4 ◦ C and lysed in lysis buffer and samples were cleared
by centrifugation at 20 000 g for 5 min at 4 ◦ C.
SEC (size-exclusion chromatography)
Cell were grown in 225 cm2 flasks until confluent, detached with
trypsin and washed with PBS. The cell pellets were lysed in gelfiltration buffer (50 mM Tris/HCl, pH 7.5, containing 150 mM
NaCl and 1 mM EDTA) and 2 % (w/v) DDM (dodecylmaltoside).
Cell debris was removed by centrifugation at 20 000 g for 10 min
at 4 ◦ C, and a buffer exchange was carried out using Vivaspin
centrifugal concentrators (molecular mass cut-off 50 000 Da) into
gel-filtration buffer containing 0.02 % DDM. For secreted protein,
c The Authors Journal compilation c 2013 Biochemical Society
184
J. Rudolf, M. A. Pringle and N. J. Bulleid
a 225 cm2 flask of confluent cells was incubated with 20 ml
of serum-free DMEM for 3 h. The medium was then removed,
centrifuged at 250 g for 5 min to remove contaminating cells
and subjected to a buffer exchange in the same fashion as the
cell lysates. For SEC, a Sephadex 200 PC3.2/30 (GE Healthcare)
column was equilibrated in gel-filtration buffer containing 0.02 %
DDM. Then, 50 μl of each of the concentrated samples was loaded
and 25 μl fractions were collected. Volumes of 18 μl of each
fraction were mixed with SDS sample buffer and analysed by
Western blotting. Western blots were quantified using ImageJ
(NIH).
QSOX1 co-assembly
HT1080 cells were transfected with equal amounts of QSOX1A–
V5 and QSOX1A–GFP or QSOX1B–V5 and QSOX1A–GFP.
After 24 h, the medium was removed, and free thiols were blocked
by incubation with 20 mM NEM (N-ethylmaleimide) (Sigma) in
PBS for 2 min on ice. After the cells were rinsed with PBS to
remove residual NEM, they were lysed by addition of RIPA buffer.
The cell lysates were processed as described above using GFPTrap® _A. The samples were analysed by SDS/PAGE (8 % gel)
and immunoblotted using anti-GFP and anti-V5 antibodies.
Figure 2
RESULTS
QSOX1A is proteolytically processed and secreted from
mammalian cells
QSOX1 has been shown previously to locate to the Golgi
apparatus and to be secreted from mammalian cells [5,23]. As
QSOX1A contains a TM domain, whereas QSOX1B does not,
it was assumed that the localization pattern reflects that of
membrane-associated compared with soluble protein. To assess
the location of the two splice variants of QSOX1, we created
stable cell lines expressing each protein tagged with a V5 epitope
at the C-terminus (Figure 1A). Intracellular expression of the
V5-tagged proteins was demonstrated for both QSOX1A and
QSOX1B (Figure 1B, left-hand panel) with multiple products
being present, probably reflecting different glycosylated forms.
We also detected V5-tagged QSOX1B, but not V5-tagged
QSOX1A, in the medium. An antibody raised against a peptide
only present in QSOX1A (Figure 1A) was able to detect this
protein not only in the cell lysate, but also surprisingly in
the medium (Figure 1B, right-hand panel). The appearance of
QSOX1A in the medium was not due to the overexpression of
the protein, as we could isolate and detect both QSOX1A and
QSOX1B from the medium of untransfected cells (Figure 1C,
HT). We were able to detect both forms in similar amounts by
first isolating glycoproteins from the medium of untransfected
cells using concanavalin A, followed by immunoblotting using
an antibody that recognizes both forms of the protein. Finally, we
showed that the secretion of QSOX1A was not cell-line-specific,
as QSOX1A was also processed and secreted following expression
in CHO cells (Figure 1D). Hence it would appear that both splice
variants are secreted from mammalian cells. The absence of the V5
epitope from secreted QSOX1A suggests that the protein becomes
proteolytically processed within the cell, although the different
mobility of the secreted QSOX1A and QSOX1B forms shows
that the processing does not generate QSOX1B from QSOX1A.
Our results also demonstrate that similar amounts of both isoforms
are expressed and secreted at least by HT1080 cells.
We have shown previously that QSOX1A does become
integrated into the ER membrane when expressed in an in vitro
c The Authors Journal compilation c 2013 Biochemical Society
Pulse–chase experiments illustrating the secretion of QSOX1A
The cells were radiolabelled for 30 min and secretion was followed by harvesting cells (A and
B) and medium (C and D) at the indicated time points. Samples were immunoisolated by
using either the anti-QSOX1A antibody bound to Protein A–Sepharose (α-1A) (A and C) or
anti-V5-coupled agarose (α-V5) (B and D). The samples were separated by SDS/PAGE and
gels were exposed to Kodak imaging film. Molecular masses of marker proteins are indicated
(in kDa).
translation system in the presence of a source of ER membranes
[5]. To determine whether the protein also becomes integrated
into the membrane in intact cells, we treated semi-permeabilized
QSOX1A–V5-expressing cells with proteinase K. In the absence
of protease, QSOX1A–V5 was detected by both the anti-QSOX1A
and the anti-V5 antibodies (Figure 1E). In the presence of
protease, the V5 epitope was removed, whereas the QSOX1A
epitope remained, demonstrating that the protein was integrated
into the membrane with the V5 epitope exposed to the protease
on the cytosolic side of the membrane. PDI was used as a control
ER-localized protein that, like QSOX1A, was only digested after
proteinase K digestion in the presence of detergent.
The accumulation of QSOX1A in the medium was clearly
observed; however, these experiments do not provide any
indication of the kinetics of secretion. To address this point,
we carried out a pulse–chase experiment (Figure 2). Newly
synthesized protein was radiolabelled for 30 min and then chased
for various times before being immunoisolated with either
the anti-QSOX1A or anti-V5 antibody. Intracellular QSOX1A
migrates as a distinct band immediately after the pulse, which
becomes progressively shifted to a slower migrating more diffuse
band during the chase (Figures 2A and 2B). This shift is most
likely to be due to processing of the oligosaccharide chains in the
Golgi apparatus. The slower migrating QSOX1A is also detected
by the anti-V5 antibody, suggesting that proteolytic processing
does not occur until after the protein has reached the Golgi
apparatus. Within 30 min of the chase, QSOX1A is detected in
the medium by the anti-QSOX1A antibody, but not by the anti-V5
antibody, and is depleted from cells after 180 min, demonstrating
the rapid processing and secretion of this protein (Figures 2C and
2D).
Proteolytic processing of QSOX1A
185
apparatus and that proteolytic processing occurs after transport
from the ER.
To investigate further the location of proteolytic processing,
we created a stable cell line expressing QSOX1A containing
a GFP tag at the C-terminus. Removal of the GFP tag caused
a clear shift in mobility of the protein when separated by
SDS/PAGE (Figure 3B, lane 1), allowing us to differentiate
between the cleaved and uncleaved forms. Only the uncleaved
form is recognized by an anti-GFP antibody (Figure 3B, lane
4) and is sensitive to digestion with both EndoH and PNGase
(Figure 3B, lanes 5 and 6). However, the cleaved form shows
resistance to digestion with EndoH, but not PNGase (Figure 3B,
lanes 2 and 3). Modification of the oligosaccharide side chain that
results in EndoH resistance occurs in the medial Golgi [24]. As
our pulse–chase experiment demonstrated that cleavage does not
occur until after some modification of the oligosaccharide side
chain in the Golgi (Figure 2B), then these results allow us to
conclude that cleavage is most likely to occur following transport
from the ER but before trafficking to the medial Golgi.
Proteolytic processing of QSOX1A occurs at multiple sites within
the ectodomain
Figure 3
Intracellular localization of QSOX1A
(A) Immunofluorescent microscopy images of fixed cells are shown. Panels (i)–(iv): localization
of the QSOX1A–V5 form stably overexpressed in HT1080 cells. Panels (v) and (vi): localization of
endogenous QSOX1A in untransfected HT1080 cells. Cells were co-stained for (i) V5
(green)/giantin (red), (ii) V5 (green)/PDI (red), (iii) QSOX1A (green)/giantin (red), (iv) QSOX1A
(green)/PDI (red), (v) QSOX1A (green)/giantin (red), (vi) QSOX1A (green)/ PDI (red). Giantin and
PDI are Golgi and ER markers respectively. Merged images are shown on the right and yellow
colour indicates co-localization. Scale bar, 20 μm. (B) Deglycosylation experiments using the
QSOX1A–GFP-expressing HT1080 cell line. Cell lysates (UT) were treated with either EndoH
(E) or PNGase (P) overnight at 37 ◦ C. Samples were separated by SDS/PAGE, transferred on
to a nitrocellulose membrane and probed for either QSOX1A (α-1A) or the GFP tag (α-GFP).
Full-length (uncleaved) and cleaved products of QSOX1A are indicated.
Subcellular location of QSOX1A processing
To identify the location of the QSOX1A processing event, we
first determined the subcellular location of the V5-tagged protein
by immunofluorescence (Figure 3A). QSOX1A–V5 co-localized
primarily with the Golgi protein giantin with some co-localization
with the ER protein PDI (Figure 3A, panels i and ii). Very similar
staining was seen with the anti-QSOX1A antibody (Figure 3A,
panel iii and iv). In addition, we carried out immunofluorescent
microscopy of the endogenous QSOX1A revealing a similar
Golgi localization (Figure 3A, panels v and vi), suggesting
that the accumulation of QSOX1A–V5 is not a consequence
of overexpression. These results, along with the pulse–chase
data, suggest that the V5-tagged protein is present in the Golgi
We used the cell line expressing GFP-tagged QSOX1A to
characterize further the cleavage products. GFP-containing
peptides were affinity-isolated from the cell lysate or medium
(Figure 4A). Similarly to what we found with the V5-tagged
protein, GFP-containing polypeptides were only isolated from the
cell lysate and not from the medium. Several cleavage products
could be isolated which migrated with apparent molecular masses
greater than that of GFP alone which has a molecular mass of
approximately 27 kDa. This result indicates that the cleavage
site is not within GFP itself. The removal of the TM domain of
QSOX1A could occur in two possible ways: either by regulated
intra-membrane proteolysis or by cleavage in the ectodomain of
the protein [25]. To distinguish between these possibilities, we
carried out live-cell imaging of the QSOX1A–GFP cell line to
determine where GFP fluorescence is localized in these cells.
Bright intracellular punctate staining is seen indicative of a Golgi
localization. In addition, the plasma membrane is clearly labelled
(Figure 4B). As cleavage of QSOX1A occurs in the Golgi, this
staining pattern would suggest that the GFP-containing cleavage
products still contain the TM domain, are membrane-localized
and have been transported to the cell surface.
To test this hypothesis, we carried out subcellular fractionation
by differential centrifugation (Figure 4C). If QSOX1A had been
cleaved at the cytosolic side of the membrane or within the
TM domain, then the cleavage product should be fractionated
with the cytosol. However, both the cleaved QSOX1A and
the cleavage products which contain the GFP tag are present
in the membrane fractions and co-fractionate with ER and
Golgi proteins (Figure 4C, left-hand panel). As a control, we
demonstrated that, when GFP alone is expressed in HT1080
cells, it co-fractionates with the cytosolic marker protein GAPDH
(Figure 4C, right-hand panel). Finally, when the two major
affinity-purified GFP-containing cleavage products were excised
from the gel and digested with trypsin, peptides corresponding
to the TM domain and the C-terminal region of the ectodomain
were identified by MS (results not shown). Taken together, these
results strongly suggest that QSOX1A cleavage occurs within the
ectodomain of the protein while the TM domain remains intact.
The large shift in mobility between QSOX1A–GFP and
cleaved QSOX1A allowed us to monitor the kinetics of cleavage
and secretion in more detail. A pulse–chase analysis revealed
c The Authors Journal compilation c 2013 Biochemical Society
186
J. Rudolf, M. A. Pringle and N. J. Bulleid
Figure 5
Identification of the cleavage sites in QSOX1A–GFP
(A) Residues Arg605 –Ala742 of QSOX1A are shown. The peptide sequence used to raise the
anti-QSOX1A antibody is highlighted in light grey and the TM domain is highlighted in dark
grey. Predicted PPC motifs are underlined; residues where cleavage occurs are numbered and the
position of the incision is indicated with a triangle. (B) Western blot of QSOX1A–GFP full-length
and cleavage products (i–iv) of different alanine mutants are shown. The GFP-containing
peptides were isolated using GFP-Trap® _A and identified by an anti-GFP (α-GFP) Western
blot. The positions of the respective alanine mutations are shown above the gel. QSOX-GFP, not
mutated; GFP, soluble GFP. (C) Samples were processed as in (B) from HT1080 cells that were
either untransfected (UT) or transfected with QSOX1A–GFP or a cleavage site mutant (CSM)
where Arg644 , Arg645 , Arg673 , Arg689 and Arg694 were mutated to alanine. Molecular masses of
marker proteins are indicated (in kDa).
Figure 4
Cleavage products of QSOX1A–GFP
(A) Western blot showing the full-length GFP-tagged form (FL) of QSOX1A and cleavage
products (CP). The cell lysate and serum-free culture medium were harvested following
3 h of incubation in serum-free medium. The GFP-containing fragments were isolated using
GFP-Trap® _A and identified by an anti-GFP Western blot. Molecular masses of marker proteins
are indicated (in kDa). (B) Live-cell image of QSOX1A–GFP-expressing HT1080 cells by
confocal microscopy. The GFP fluorescence is detected in the Golgi, the cell membranes and
small vesicles. Scale bar, 20 μm. (C) Western blot analysis of the fractionation of cellular
components by differential centrifugation. Cell lysates were homogenized and followed by two
consecutive centrifugation steps at 1000 g and 16 000 g . The pellet of the first step contains
nuclear membranes, the ER and the Golgi. The pellet (p) of the 16 000 g centrifugation step
enriches the cell membranes and the supernatant (sn) represents the cytoplasm. Nitrocellulose
membranes were probed for cleaved and full-length forms of QSOX1A–GFP (α-1A), the
GFP-tagged full-length form (α-GFP, FL) and cleavage products (α-GFP, CP), the ER marker PDI
(α-PDI), the Golgi marker GM130 (α-GM130), a marker for the cell membrane (α-MHC I) and a
cytoplasmic marker (α-GAPDH). Cell lysates were prepared from HT1080 cells stably expressing
QSOX1A–GFP (HT1080:QSOX1A-GFP) and from HT1080 cells transiently transfected with
soluble GFP (HT1080:GFP) respectively. (D) Pulse–chase experiments illustrating the cleavage
of QSOX1A–GFP. The samples were radiolabelled for 30 min and secretion followed by harvesting
cells and medium at the indicated time points. Samples were immunoisolated by using either
the anti-QSOX1A antibody bound to Protein A–Sepharose or GFP-Trap® _A. The samples were
c The Authors Journal compilation c 2013 Biochemical Society
processing of QSOX1A–GFP within the first 20 min of the chase,
presumably following its transport from the ER to the Golgi
(Figure 4D, upper panel). Cleaved QSOX1A appears in the
medium shortly after intracellular processing, demonstrating
rapid secretion from the Golgi. The GFP-containing products
also appear at the same time, with the larger product seen first,
followed by the small products at later time points, consistent with
sequential cleavage events (Figure 4D, lower left-hand panel).
No radiolabelled products were immunoisolated with the GFPTrap® _A from the medium, confirming the absence of secretion
of the uncleaved protein or the cleavage products.
Identification of the cleavage site
The results above define the location of the cleavage site in
QSOX1A as occurring between the peptide sequence used to raise
the anti-QSOX1A antibody and the TM domain (Figure 5A).
To identify potential proteases responsible for the cleavage of
QSOX1A, we first searched the UniProt database [26] for all proteases that are known to be present within the human ER and Golgi
apparatus (Supplementary Table S1 at http://www.biochemj.org/
bj/454/bj4540181add.htm). The resulting list of proteases was
analysed manually with regard to their substrate specificities
and consensus cleavage patterns. Three of the PPCs (proprotein
separated by SDS/PAGE and gels were exposed to Kodak imaging film. Cleavage products
are marked by arrows. Molecular masses of marker proteins are indicated (in kDa). IP,
immunoprecipitation.
Proteolytic processing of QSOX1A
convertases), PCSK3, PCSK6 and PCSK7, particularly stood out
as they cleave at dibasic motifs, two of which are present in
the QSOX1A amino acid sequence. The QSOX1A amino acid
sequence also was analysed for potential cleavage sites using the
ProP 1.0 Server [27]. Two of the predicted PPC cleavage sites
are present in the region of interest with cleavage occurring Cterminally of residues Arg645 and Arg673 (Figure 5A). In addition,
a third potential site that contains a consensus site for cleavage
by the PPC family (i.e. K/R-Xn -K/R where n = 0, 2, 4 or 6 and X
is any amino acid) [28], is present (Arg689 –Arg692 ). To determine
whether these sites are indeed used to process QSOX1A, we
carried out mutagenesis using the QSOX1A–GFP construct as a
template. Following transfection into HT1080 cells, we monitored
the appearance of the cleavage products. In agreement with earlier
observations (Figure 4D), cleavage does not occur at a single site.
The K644A/R645A mutant led to the disappearance of a minor
product (Figure 5B, i). The cleavage product (Figure 5B, ii) is
a result of incision after Arg673 . Furthermore, a triple mutation
of Arg689 , Arg692 and Arg694 led to the reduction of additional
cleavage products (Figure 5B, iii). Preventing the cleavage at
Arg689 /Arg692 /Arg694 gave rise to a faster migrating cleavage
product barely seen with the wild-type protein (Figure 5B, iv).
When multiple PPC motifs were mutated (Arg644 , Arg673 , Arg689 ,
Arg692 and Arg694 ), none of the major cleavage products were seen
(Figure 5C), although a small amount of cleaved material was
secreted (results not shown). Hence no single mutation prevented
cleavage, indicating that multiple sites may be recognized by
the protease(s) and that each site is recognized independently.
Taken together, these results suggest multiple, but specific, PPC
cleavage sites within QSOX1A which result in the release of the
ectodomain from its membrane anchor.
QSOX1A forms a complex before proteolytic processing
The synthesis of QSOX1A as a precursor protein that becomes
cleaved may provide a mechanism for the regulation of protein
function. To determine whether there was any effect of proteolytic
processing on the interaction of QSOX1A with itself or with
other proteins in cells, we stabilized interactions using a thiolspecific cross-linking agent (Figure 6). Using the QSOX1A–
GFP-expressing cell line, a higher-molecular-mass product was
detected using the anti-GFP antibody that was apparent only
following cross-linking (Figure 6A). This result indicates the
presence of uncleaved QSOX1A–GFP in complex either with
itself or with other protein(s). When the cell lysates were separated
on a higher percentage gel, no cross-linking of the GFP cleavage
products was observed. This suggests that the ectodomain is
required for stabilizing the cross-link or that the cysteine residues
involved in the cross-linking are not present in the GFP cleavage
products.
We also carried out cross-linking experiments using the
QSOX1A–V5 cell line. For this, cellular proteins were radiolabelled and cross-linked, and cell lysates were subjected to immunoisolation, first with the anti-V5 antibody, then the V5immunodepleted lysates were subjected to immunoisolation with
the anti-QSOX1A antibody (Figure 6B). The anti-V5 antibody
only detects the uncleaved QSOX1A–V5 form. In accordance
with results described above, a product was isolated that was
only present following cross-linking. In addition, the lysate
depleted of V5-reactive proteins does not contain the cross-linked
product, demonstrating further that only the uncleaved QSOX1A–
V5 forms a complex. Finally, when the QSOX1B–V5 cell line
was analysed in a similar experiment, no cross-linked products
were seen following immunoisolation with the anti-V5 antibody
(Figure 6C). This result implies that the appearance of a distinct
Figure 6
187
Dimerization of full-length QSOX1A
Thiol-cross-linking experiments are shown in the presence ( + ) or absence ( − ) of 0.1 mM
BMH. (A) Cell lysates were prepared from the QSOX1A–GFP-overexpressing cell line and
analysed by Western blotting following separation by SDS/PAGE (8 % and 11 % gels
respectively). Cleavage products (CP) are as indicated. (B and C) Proteins were labelled for
30 min in 35 S-containing medium, and cells were harvested after 30 min of chase and subjected
to BMH treatment as indicated. Cell lysates from a QSOX1A–V5- (B) and a QSOX1B–V5- (C)
overexpressing cell line were first depleted of V5-containing polypeptides using anti-V5–agarose
(α-V5). V5-immunodepleted lysates were then subjected to immunoisolation with anti-QSOX1A
(α-1A). (D) Thiol-cross-linking was carried out as described in (A) using HT1080 cell lines
expressing the QSOX1A–V5 C713A mutant form (transient) or the QSOX1A–V5 control (stable).
Following immunoisolation with anti-V5–agarose (α-V5), proteins were detected in a Western
blot using the anti-1A (α-1A) antibody. In (A), (B) and (D), the cross-linked product is indicated
by an asterisk. IP, immunoprecipitation; WB, Western blot. Molecular masses are indicated (in
kDa).
cross-linked product is a specific property of uncleaved QSOX1A.
Taken together, these results indicate that QSOX1A forms a
complex with itself or with another protein before cleavage.
To identify the specific residues involved in the thiol-specific
cross-linking of QSOX1A, we constructed a series of cysteine
mutants. The only mutation that affected the cross-linking was
C713A which is present within the TM domain of QSOX1A
(Figure 6D). Hence the TM domain must be in close proximity
to another QSOX1A molecule or other membrane proteins before
cleavage. The absence of cross-linking of the cleavage products
that contain Cys713 underlines the fact that the ectodomain is
required for a stable association of the TM domain. Furthermore,
analysis of the cross-linked product by MS revealed only the
presence of peptides present in QSOX1A (results not shown).
These results suggest that the cross-linked product is a dimer of
QSOX1A.
The cross-linking approach allowed us to evaluate the association of QSOX1A in intact cells, but tells us little about the size
of any complexes formed. To provide an alternative approach to
determine complex formation, we separated cell lysates from the
QSOX1A–V5-expressing cell line by SEC (Figure 7A). There
was a clear separation of the uncleaved V5-tagged protein and
the cleaved QSOX1A. Both were eluted as relatively broad peaks
with the cleaved material eluting as a dimer (∼ 180 kDa), whereas
the uncleaved protein eluted as higher-molecular-mass material
c The Authors Journal compilation c 2013 Biochemical Society
188
Figure 7
J. Rudolf, M. A. Pringle and N. J. Bulleid
Analytical SEC of QSOX1
Samples were separated on a S200 PC3.2/30 SEC column (GE Healthcare) and fractions were analysed by Western blotting. (A) Cell lysate from a QSOX1A–V5-overexpressing cell line was prepared
in gel-filtration buffer containing 0.02 % DDM. Upper panel: normalized Western blot quantification results (relative amount of QSOX1A) are plotted against the SEC elution volume (ml). Each data
point represents a fraction. Lower panel: Western blots of SEC fractions were co-probed with anti-V5 (α-V5) and anti-QSOX1A (α-1A) antibodies. Average molecular mass (Mr × 103 ) for each
fraction is indicated above the gels. (B) QSOX1 secreted into serum-free medium from cell lines stably expressing QSOX1A–V5 and QSOX1B–V5 respectively. The medium was removed from
cells after 3 h and a buffer exchange was carried out into gel-filtration buffer containing 0.03 % Triton X-100 using Vivaspin 50 000 Da molecular-mass cut-off concentrators. The samples were
concentrated and analysed as described above.
(∼ 600–1200 kDa). SEC of the secreted QSOX1A or QSOX1B
revealed the presence of a peak equivalent to a dimer and with no
higher-molecular-mass material (Figure 7B). From these results
and the cross-linking results, we can conclude that uncleaved
QSOX1A forms a complex within cells before the formation of a
dimeric species upon cleavage.
The ability of QSOX1A to form a dimer led us to consider
the possibility that QSOX1B may be able to co-assemble with
QSOX1A. To test this possibility, we carried out co-transfection of
HT1080 cells with V5-tagged QSOX1B or V5-tagged QSOX1A
and GFP-tagged QSOX1A. Following immunoisolation with the
GFP-Trap® _A, we carried out immunoblotting to determine
whether either V5-tagged QSOX1 isoform was co-isolated with
QSOX1A–GFP (Figure 8). QSOX1A–V5 and QSOX1B–V5 were
co-isolated, as judged by their presence in the immunoisolate
(Figure 8A, lanes 1 and 2). As a control, we showed that
QSOX1A–V5 could not be detected by immunoblotting following
GFP-Trap® _A immunoisolation in the absence of QSOX1A–GFP
(Figure 8B). These results indicate that QSOX1A can assemble
not only with itself, but also with QSOX1B before cleavage of the
c The Authors Journal compilation c 2013 Biochemical Society
TM domain, with the consequence that QSOX1B secretion could
be dependent on the proteolytic cleavage of QSOX1A.
DISCUSSION
Previous research has provided us with a detailed understanding of the enzymatic function and structure of the QSOX1
family of sulfhydryl oxidases [3,6], yet our knowledge of their
function in vivo is limited. In the present study, we provide
compelling evidence that both the short and long forms of
QSOX1 are efficiently secreted from cells and that QSOX1A
undergoes intracellular proteolytic processing. The efficiency of
secretion would argue for an extracellular role for this enzyme
as the presence of QSOX1 within the secretory pathway will be
transitory. However, significant accumulation of the enzyme does
occur in the Golgi apparatus and little, if any, QSOX1A staining
is found at the cell surface. The accumulation of the enzyme in
the Golgi would suggest that trafficking of QSOX1A to the cell
surface requires the cleavage of the TM domain. Such regulated
Proteolytic processing of QSOX1A
Figure 8
Interactions between QSOX1A and QSOX1B forms
(A) HT1080 cells were co-transfected either with QSOX1A–V5/QSOX1A–GFP or
QSOX1B–V5/QSOX1A–GFP as indicated above the blots. Cell lysates were subjected to
anti-GFP (α-GFP) immunoisolation followed by Western blot analysis identifying either V5or GFP-tagged QSOX1 forms as indicated on the right-hand side. (B) The control experiment
shows that QSOX1A–V5 does not interact non-specifically with the GFP-Trap® _A resin. The
lysates from a QSOX1A–V5-overexpressing cell line was incubated first with GFP-Trap® _A
and then the immunodepleted lysate was subjected to immunoisolation with anti-V5–agarose
(α-V5). Molecular masses of marker proteins are indicated (in kDa). IP, immunoprecipitation;
WB, Western blot.
trafficking would provide a mechanism to control the level of
enzyme released from cells.
Although the proteolytic cleavage of QSOX1A provides a way
to regulate its secretion, no such restriction would be placed
upon the secretion of QSOX1B. However, the ability of QSOX1A
before its cleavage to interact with QSOX1B suggests a mechanism for controlling the secretion of QSOX1B. The interaction of
QSOX1B with membrane-integrated QSOX1A would cause the
secretion of both proteins to be dependent on the cleavage event.
The ectodomain of QSOX1A is identical with that of QSOX1B
apart from a C-terminal extension of approximately 104 amino
acids in QSOX1A, so it is not too surprising that they can interact
within the secretory pathway. Our analysis of the relative levels
of secretion of these two forms of QSOX would suggest that they
are secreted in approximately stoichiometric amounts at least from
HT1080 cells. Hence the intracellular proteolytic processing of
QSOX1A may well influence the concentration of both forms of
this enzyme in the extracellular space.
Although it is apparent from our results that QSOX1A is cleaved
within the Golgi, the exact identity of the protease(s) catalysing
this event remains to be determined. Our mutagenesis studies
have identified a number of sites for the incision that fit the
consensus cleavage site for the PPC family [28]. This family of
serine proteases cleaves proteins at basic sites during their passage
through the secretory pathway. Some of the family members are
resident in the Golgi and would be potential candidates for the
QSOX1A protease. Previously, one member of the PPC family
(PCSK5) was found to be co-immunoisolated from rat brain with
a QSOX antiserum [29], although this enzyme seems to be poorly
expressed in HT1080 cells [28]. We have carried out several
experiments to try to inhibit cleavage with protease inhibitors,
but none were able to completely prevent cleavage (results not
shown). It may well be that several enzymes are capable of
catalysing this cleavage event, precluding the use of inhibitors
to identify the specific protease(s) involved.
The functional significance of the intracellular complex
formation and membrane cleavage of QSOX1 is unclear, but it is
tempting to speculate that enzymatic function could be regulated
189
by subtle conformational changes occurring following proteolytic
processing. QSOX1 is an efficient catalyst of disulfide formation
with broad substrate specificity [30]. The fact that a product of
the reaction of QSOX1 with protein thiols is hydrogen peroxide
would suggest that the enzyme needs to be regulated to prevent
excessive build-up of this reactive oxygen species [31]. Ero1
is tightly regulated by the formation of non-catalytic disulfides
to prevent excessive hydrogen peroxide production. The noncatalytic disulfides prevent disulfide transfer to the substrate [32–
34]. QSOX1 would appear to have no such regulatory mechanism
and therefore, if unregulated, should be active both within and
outside the ER during transit through the secretory pathway. It is
known that soluble QSOX1 undergoes a dramatic conformational
change during its enzymatic cycle [3]; tethering the enzyme to
the membrane via a TM domain may well prevent or restrict such
conformational changes leading to an inhibition of activity.
QSOX1 has been shown to introduce disulfides into a wide
range of protein substrates; the only common characteristic is that
the proteins need to be in a partially unfolded state [30]. Unlike
the disulfide-exchange protein PDI, the thioredoxin domain of
QSOX1 does not possess isomerase activity, indicating that the
enzyme is equally proficient at introducing non-native as well as
native disulfides [35]. Such an activity would restrict the yield of
correctly folded protein as any non-native disulfide would not be
resolved [31]. Within the ER, PDI could remove any non-native
disulfides formed by QSOX1, providing an efficient mechanism
for disulfide formation in newly synthesized proteins. Outside the
ER, most proteins are likely to be folded correctly as they will
have escaped the ER quality control [36]. Our identification of
QSOX1 as an efficiently secreted catalyst of disulfide formation
would suggest that its substrates are likely to be essentially folded,
but require a catalyst to introduce regulatory disulfides to activate
or inhibit protein function. Alternatively, QSOX1 may be required
to stabilize multisubunit complexes by the formation of interchain
disulfides.
AUTHOR CONTRIBUTION
Neil Bulleid and Jana Rudolf designed the experiments and wrote the paper. Jana Rudolf
and Marie Pringle conducted the experiments.
ACKNOWLEDGEMENTS
We acknowledge the generosity of all our colleagues for contributing reagents and members
of the Bulleid group and Gordon Lindsay for a critical reading of the paper before
submission.
FUNDING
This work was funded by the Wellcome Trust [grant number 088053].
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Biochem. J. (2013) 454, 181–190 (Printed in Great Britain)
doi:10.1042/BJ20130360
SUPPLEMENTARY ONLINE DATA
Proteolytic processing of QSOX1A ensures efficient secretion of a potent
disulfide catalyst
Jana RUDOLF*, Marie A. PRINGLE* and Neil J. BULLEID*1
*Institute of Molecular, Cellular and Systems Biology, College of Medical Veterinary and Life Sciences, Davidson Building, University of Glasgow, Glasgow G12 8QQ, U.K.
Table S1
Human proteases present in the ER and Golgi
Results were returned upon a Uniprot database (http://www.uniprot.org) enquiry using the following search terms: Human/Protease/Golgi Stack [OR] Human/Protease/Endoplasmic Reticulum.
Proprotein convertases are highlighted in bold.
Entry
Gene name
Protein names
P56817
Q9Y5Z0
A6NHC0
Q9Y646
O60344
Q9NZ08
Q6P179
Q7Z2K6
O75844
P09958
Q92643
Q8TCT9
Q92876
Q14703
O75900
P29122
Q16549
P49768
P49810
P67812
Q9BY50
Q9Y6A9
Q15005
P61009
Q8TCT7
Q8IUH8
Q8TCT6
P57727
Q9UI38
O94966
Q8NFA0
P09936
Q9NUQ7
Q96JH7
BACE1
BACE2
CAN8
CBPQ
ECE2
ERAP1
ERAP2
ERMP1
FACE1
FURIN
GPI8
HM13
KLK6
MBTP1
MMP23
PCSK6
PCSK7
PSN1
PSN2
SC11A
SC11C
SPCS1
SPCS2
SPCS3
SPP2B
SPP2C
SPPL3
TMPS3
TSP50
UBP19
UBP32
UCHL1
UFSP2
VCIP1
β-Secretase 1 (membrane-associated aspartic protease 2)
β-Secretase 2 (membrane-associated aspartic protease 1)
Calpain-8
Carboxypeptidase Q (plasma glutamate carboxypeptidase)
Endothelin-converting enzyme 2
Endoplasmic reticulum aminopeptidase 1 (type 1 tumour necrosis factor receptor shedding aminopeptidase regulator)
Endoplasmic reticulum aminopeptidase 2
Endoplasmic reticulum metallopeptidase 1
CAAX prenyl protease 1 homologue (farnesylated protein-converting enzyme 1, zinc metalloproteinase Ste24 homologue)
Furin (paired basic amino acid residue-cleaving enzyme, PACE)
GPI (glycosylphosphatidylinositol)-anchor transamidase
Minor histocompatibility antigen H13 (intramembrane protease 1, signal peptide peptidase)
Kallikrein-6
Membrane-bound transcription factor site-1 protease (subtilisin/kexin isoenzyme 1, SKI-1)
Matrix metalloproteinase-23
Proprotein convertase subtilisin/kexin type 6 (paired basic amino acid cleaving enzyme 4, PACE4)
Proprotein convertase subtilisin/kexin type 7 (proprotein convertase 7, PC7; proprotein convertase 8, PC8)
Presenilin-1 (PS-1)
Presenilin-2 (PS-2)
Signal peptidase complex catalytic subunit SEC11A
Signal peptidase complex catalytic subunit SEC11C
Signal peptidase complex subunit 1 (12 kDa subunit)
Signal peptidase complex subunit 2 (25 kDa subunit)
Signal peptidase complex subunit 3 (22/23 kDa subunit)
Signal peptide peptidase-like 2B (intramembrane protease 4)
Signal peptide peptidase-like 2C intramembrane protease 5)
Signal peptide peptidase-like 3 (intramembrane protease 2)
Transmembrane protease serine 3
Probable threonine protease PRSS50 (testis-specific)
Ubiquitin C-terminal hydrolase 19
Ubiquitin C-terminal hydrolase 32
Ubiquitin C-terminal hydrolase isoenzyme L1
Ufm1-specific protease 2
Deubiquitinating protein VCIP135
Received 13 March 2013/23 May 2013; accepted 28 May 2013
Published as BJ Immediate Publication 28 May 2013, doi:10.1042/BJ20130360
1
To whom correspondence should be addressed (email neil.bulleid@glasgow.ac.uk).
c The Authors Journal compilation c 2013 Biochemical Society
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